JP2007515740A - Optical disc for storing both data requiring defect management and real-time AV data - Google Patents

Abstract

  An optical disc (1) for storing digital data, the optical disc storing a first storage area (10) for storing a first type of digital data and a second type of digital data A second storage area (20). Each of the first storage area and the second storage area has a user data area (11, 21). Furthermore, these storage areas (10.20) are logically independent. The second storage area (20) has defect management areas (22a, 22b) associated with the user data area (21) of the second storage area (20) for storing defect management data. .

Description

  The present invention relates generally to the field of optical disks for storing digital data, and more particularly to the field of optical disks for storing both digital data and digital real-time audio / video data that require support for defect management. .

  Today's optical disc may be, for example, a CD-ROM (Compact Disc Read Only Memory) disc, a CD-R (Recordable) disc, or a DVD (Digital Versatile Disc) for storing digital information. Disks may have different storage capacities and different data rates for transferring data to or reading data from the disk. Providing audio / video data for real-time recording / reading requires high data transfer rates.

  One optical disc that supports real-time recording / reading of audio / video data is a Blu-ray disc. When using short wavelength blue-violet lasers, Blu-ray discs successfully minimize the beam spot size by setting the numerical aperture (NA) in the field lens that focuses the laser to 0.85. In addition, by using a disc structure with a 0.1 mm light transmissive protective layer, Blu-ray discs reduce aberrations caused by disc tilt. This also improves the reading of the disc and increases the recording density. The tracking pitch of the Blu-ray disc is reduced to 0.32 μm, which is approximately half the tracking pitch of a regular DVD, and high-density recording of up to 27 GB is achieved on a single-side disc.

  Since the Blu-ray Disc uses the MPEG-2 transport stream compression technology, which is a global standard, it is highly compatible with digital broadcasting for real-time audio / video recording, and a wide range of content can be recorded. Blu-ray discs can record digital high-resolution broadcasts while maintaining high quality, and can also record other data simultaneously with video data when received together.

  In order to read / write digital data on the optical disk by the drag and drop function, it is preferable to provide physical defect management in the drive. Thus, the optical disc must have a dedicated area in which defect management data may be provided in the recordable area.

  Blu-ray video real-time requirements, ie 36 Mb / s read / write and 800 ms seek, meet the maximum read-write speed of Blu-ray discs and devices. However, these requirements are not compatible with defect management. This means that there is currently no room for additional delay introduced by defect management while playing or recording digital real-time Blu-ray video data.

  In the Blu-ray standard, a disc is a single partition that includes either a continuous area without defect management or an area with defect management. The standard also requires a specific file system, namely BDFS (Blu-Ray Disc File System). UDF (Universal Disc Format) is a file system for optical disks. BDFS cannot manage as many files as UDF, which makes BDFS impractical for PC data applications where tens of thousands of files can be expected on a 27 GB disk. BDFS is an integral part of the Blu-ray disc and is extremely useful for storing data with real-time requirements. On the other hand, UDF may be used with Blu-ray discs in a PC environment. UDF may be used for Blu-ray Discs with defect management turned on and capable of holding tens of thousands of files. The Blu-ray Disc standard turns on defect management and at the same time makes it impossible to use the defect management for BDFS. This is because the logical to physical relationship, i.e. the logical zero point, is at different positions on the disk and is different in these two cases. Thus, in order to meet the conflicting requirements of reading / writing digital data with support for defect management according to the Blu-ray standard and reading / writing real-time audio / video data, a separate disc is provided. There must be.

  The present invention overcomes the deficiencies noted above in the art and solves the aforementioned problems by providing an optical disc having at least two storage areas that are logically separated.

  According to a first aspect of the invention, a first storage area is reserved for storing a first type of digital data such as audio / video data having real-time requirements that are incompatible with defect management. An optical disc is provided. A second storage area is reserved for storing data of a second type of digital data, such as data supporting a drag and drop function, for example, data in need of defect management support. Only the second storage area has a defect management area associated with storing the defect management data.

  The first and second storage areas of the disc are separately accessible and are independent of each other.

  According to a second aspect of the invention, a method is provided for reading digital data from or writing digital data to an optical disc. According to the method, if the first storage area is read by the first access means when the first type of digital data is to be read from or written to the first storage area, Accessed. The second storage area is accessed by the second access means when digital data requiring defect management is to be read from or written to the second storage area.

  According to a third aspect of the present invention there is provided an optical disc drive having an optical reader / writer, a drive controller, means for receiving digital data and means for receiving an optical disc. The drive controller receives the instruction to read the first type of data from the first storage area of the optical disk or the instruction to write the first type of data to the first storage area in the first storage area. Configured to access. Further, the drive controller receives the instruction to read the second type of data from the second storage area of the optical disc or the instruction to write the second type of data to the second storage area. Configured to access the region, the second type of data requires support for defect management.

  According to a fourth aspect of the present invention, there is provided a computer system having a disk drive according to the present invention. Separate drive letters within the computer operating system may allow separate and independent access to the first and second storage areas of the disk. Alternatively, the first storage area can be directly accessed via an application program having software readable instructions that allow access to the first storage area.

  An advantage of the present invention is that separate types of digital data can be provided on a high speed, high density optical disc, such as a Blu-ray disc. Furthermore, there is an advantage that digital data that is not compatible with defect management and digital data that requires defect management support can be stored on the same disk. If the computer system is provided with a disk drive that can access a separate storage area of the disk, the data may be read / written independently by the computer system. Another advantage of the present invention is that if the storage area reserved for real-time data is provided as the first storage area of the disk, the disk does not allow for defect management in the first area. It is compatible with disc recorders known in the field.

  Other objects, features and advantages of the present invention will become apparent from the following detailed description of the invention which refers to the accompanying drawings.

  FIG. 1 shows a schematic diagram of a part of an optical disc 1 according to an embodiment of the present invention. A plan view of the disk 1 is shown in FIG. The disc 1 has a first storage area 10 for storing digital data relating to the first type of data. A second storage area 2 is provided for storing digital data relating to the second type of digital data.

  As shown in FIGS. 1 and 2, the disk 1 has two physically separated partitions and two logically independent areas. However, the disc has three or more partitions as long as at least one area is reserved for the first type of digital data and at least one area is reserved for the second type of digital data. You may have. The disk 1 has a large storage density and a high data transfer rate. Thus, the disc is suitable for storing audio / video data that may be read from or written to the disc 1 in real time. When using a 405 nm blue-violet semiconductor laser with a 0.85 NA field lens and a 0.1 mm light transmission protection disk layer structure, disk 1 can record up to 27 GB of video data on a 12 cm single-sided phase change disk. it can. The data transfer rate of the Blu-ray disc is nominally 36 Mbps. The maximum transfer speed is unlimited depending on the maximum rotation speed of the disk, and the minimum transfer speed is zero. Thus, real time data read / write is supported.

  According to the present invention, the first type of data is digital data that does not support defect management and has real-time constraints such as 36 Mbps read / write and 800 ms seek, such as real-time audio / video data. Thus, the first type of data may be read / written in real time. The second type of digital data is any type that does not have real-time restrictions such as digital data that requires defect management, for example, data that can be read / written by a drag-and-drop function.

  According to the present invention, the first storage area 10 may be provided as the first, ie, innermost storage area of the disk 1. Thus, the disc 10 can be used with a Blu-ray reader / writer known in the art, such as a reader / writer that does not allow for defect management. However, the second storage area 20 will not be accessed by reader / writer devices known in the art. However, the use of the reader / writer according to the invention has the advantage that any of the storage areas 10 and 20 may be provided as the first storage area of the disc 1.

  The first storage area 10 has a user data area 11. The user data area 11 has high-speed data read / write capability without defect management. Data recorded in the first storage area is written / read at random. A track, or a number of consecutive tracks, may be written randomly, ie not written sequentially. The real-time constraint specifies a minimum size of these tracks of 12 MB, a maximum access time of 800 ms, and a nominal read / write speed of 36 Mbps.

  The second storage area 20 may support defect management in the disk drive, as is preferred for drag and drop support. When used in a computer, a file may be transferred or copied, for example, from a hard disk drive to an optical disk by simply dragging a link in the operating system to the drive name for the second storage area, and vice versa It is the same. In order to support defect management, the second storage area 20 has at least one user data area 21 and at least one defect management area 22a. 1 and 2, a second defect management area 22b is also provided, and defect management data is distributed between these areas. However, instead of the two areas, one large defect management area may be provided.

  When two defect management areas are provided, one area is a “main data area”, and the other area is an area in which a replacement of a defect location in the main data area is stored. Defect data with alternative locations may be continuous or fragmented. The “main data” area may also be continuous or fragmented. Thus, these two regions may also be interleaved using, for example, a Mt Rainier interleaving scheme.

  Data is fragmented in the user data area 21 of the second storage area. Thus, data may be stored continuously or randomly at different locations in the user data area.

  The disk 1 is partitioned so that the storage areas 10 and 20 may be accessed independently. The size of each section may be determined in advance or may be determined by the user. Further, the size of each partition may be changed by the user by studying the BDFS and UDF files with a software tool such as Partition Magic from Norton Utilities. Such a software tool can reassign partitions as needed and change the boundary position of the two partitions. Each partition is logically addressed by the user. Each partition may be viewed as two separate disks, with each partition having a logical zero. Alternatively, each partition has its own address space, the first space starts with zero, has a maximum value of M-1 addresses (0 ≦ M ≦ 22-27 GB), the second space starts with M, N −1 (N is the disk size (22 to 27 GB), that is, 0 ≦ M ≦ N ≦ 22 to 27 GB).

  FIG. 3 is a schematic diagram of a disk drive 30 according to the present invention. The disk drive 30 has means 36 for receiving the disk 1 when the disk 1 is inserted into the drive 30. The drive 30 also reads / writes digital data 31 such as an optical pick-up, such as means for rotating the disk, such as an electric motor (not shown), and transferring data to / from the disk 1. It also has means for A digital signal processor (DSP) 32 may be provided to process data received from or sent to the read / write means 31.

  The DSP 32 controls, for example, one or more memories such as a motor, a demodulator, a RAM (Random Access Memory) and a ROM (Read Only Memory), a defect management controller for executing defect management, and an interleaver / deinterleaver. You may have a controller for.

  The drive controller 33 is configured to control the disk drive 30. The drive controller is configured to detect whether the data received via the interface 37 having the first input unit 34 and the second input unit 35 has real-time restrictions or real-time constraints. This is because the read / write command is received from the first access means such as the first drive name (for example, D :) 40 of the computer 41 to which the disk drive 30 is connected via the first input unit 34. It may be detected. When it is detected that the read / write instruction relates to a first type of data, such as an instruction received from the first drive name, the read / write means 31 is directed to the first storage area 10. Alternatively, the read / write instruction may relate to a second type of data, for example, the instruction is received from a second access means such as a second drive letter (eg, E :) 42 of the computer 41. In this case, the read / write means is directed to the second storage area 20.

  The computer system 41 includes a controller 43 such as a central processing unit (CPU) for executing computer readable instructions embodied on a hard disk. The present invention is not only usable with computer systems. The present invention can be used with any device having a controller for providing instructions to the disk drive 30 regarding the first and second types of data.

  To read / write a digital data file, the user of computer 41 simply drags a link from the drive name of computer 41, such as drive name C: (usually used as the drive name of the hard disk drive) to the file, The file may be dropped at the second drive name 42 indicated by the computer operating system. Alternatively, the user may wish to access real-time audio / video files on disc 1. In this case, the first drive name 41 will be entered and the drive controller 33 will direct the read / write means 31 to the first storage area 10. The first storage area may be accessible only from an application executed by the computer. In this case, the application program accesses the first storage area 10 of the disk 1, and the computer-readable program is such that the real-time data is automatically read from / written to the first storage area 10. Will have orders.

  FIG. 4 illustrates the steps to be performed by the method of the present invention for accessing the first storage area 10 or the second storage area 20. In the first step 100, an instruction to read data from the first storage area 10 or the second storage area 20 or to write data to the first storage area 10 or the second storage area 20 is received from the computer 41. . Then, in step 110, it is determined whether the read / write instruction has been executed by the first access means or the second access means of the computer 41, i.e. what type of data the instruction relates to. If the instruction is for the first type of data, the procedure continues at step 120. In step 120, the first storage area 10 is accessed to read data from or write data to the disk 1. Alternatively, the procedure continues from step 110 to step 130 if the instruction is for a second type of data. In step 130, the second storage area 20 is accessed to read data from the disk 1 or write such data to the disk 1 that requires support for defect management. Then, in step 140, the digital data is read from or written to disk 1, and the procedure ends.

  The invention has been described with reference to specific embodiments. However, implementations other than those described above, for example, the above-described methods in hardware or software, may also be within the scope of the appended claims.

  The term “comprising” does not exclude the presence of other elements and steps, and the singular term does not exclude a plurality, but a single processor or other unit may claim May perform the functions of several units or circuits listed in.

  The present invention is not limited to the appended claims.

FIG. 1 is a schematic view of a part of an optical disc according to the present invention. FIG. 2 is a plan view of an optical disc according to the present invention. FIG. 3 is a block diagram of a disk drive connected to the computer system. FIG. 4 is a flowchart of the method according to the invention.

Claims (11)

  An optical disc for storing digital data, the optical disc having a first storage area for storing a first type of digital data and a second storage for storing a second type of digital data The first storage area and the second storage area each have a user data area, and the first storage area and the second storage area are logically independent, The storage area has high-speed data read / write characteristics without defect management, and the second storage area has data read / write characteristics that require defect management support. At least one associated with the user data area of the second storage area for storing defect management data Optical disc and having an I defect management area. The optical disc according to claim 1,
The first type of data is real-time audio / video data that is not compatible with defect management, and the second type of data is digital data requiring defect management support. . The optical disc according to claim 1,
The optical disk, wherein each of the first storage area and the second storage area has a logical zero or its own address space. The optical disc according to claim 1,
An optical disc, wherein the first storage area and the second storage area of the disc are independently accessible. The optical disc according to claim 1,
An optical disc, wherein ranges of the first storage area and the second storage area are fixed. The optical disc according to claim 5, wherein
The optical disk, wherein the first storage area and the second storage area can be changed during use. The optical disc according to claim 1,
An optical disc characterized in that the disc has a nominal data transfer rate of 36 Mbps. A method of reading digital data from an optical disc or writing digital data to an optical disc, wherein the optical disc has a first storage area for storing a first type of digital data, and a logical relationship with the first storage area. A second storage area for storing a second type of digital data that requires support for defect management, and is independent of the first storage area and the second storage area Are methods each having a user data area,
Accessing the first storage area if the first type of digital data is to be read from or written to the first storage area; and A method comprising: accessing a second storage area when two types of digital data are to be read from or written to the second storage area . An optical disk drive having an optical reader / writer, a drive controller, means for receiving digital data and means for receiving an optical disk, the drive controller comprising:
An instruction to read the first type of data from the first storage area in the first storage area of the optical disk received by the means for receiving the optical disk or the first type of data in the first storage area; A first access means for accessing in response to receiving an instruction to write the data, and a command to read a second type of data from the second storage area into the second storage area of the optical disc or the first Having a second access means for accessing in response to receiving an instruction to write the second type of data to the second storage area, the second type of data requires support for defect management An optical disc drive characterized by that.   A computer system comprising the optical disk drive according to claim 9.   A computer program embodied on a computer readable medium having computer readable instructions that, when executed by a computer, causes the method of claim 8 to be performed.

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